Bio Prospecting of Endophytes and PGPRs in Artemisinin Production for the Socio-economic Advancement.

The growing demand for Artemisia annua plants in healthcare, food, and pharmaceutical industries has led to increased cultivation efforts to extract a vital compound, Artemisinin. The efficacy of Artemisinin as a potent drug against malaria disease is well established but its limited natural abundance. However, the common practice of using chemical fertilizers for maximum yield has adverse effects on plant growth, development, and the quality of phytochemicals. To address these issues, the review discusses the alternative approach of harnessing beneficial rhizosphere microbiota, particularly plant growth-promoting rhizobacteria (PGPR). Microbes hold substantial biotechnological potential for augmenting medicinal plant production, offering an environmentally friendly and cost-effective means to enhance medicinal plant production. This review article aims to identify a suitable endophytic population capable of enabling Artemisia sp. to thrive amidst abiotic stress while simultaneously enhancing Artemisinin production, thereby broadening its availability to a larger population. Furthermore, by subjecting endophytes to diverse combinations of harsh conditions, this review sheds light on the modulation of essential artemisinin biosynthesis pathway genes, both up regulated and down regulated. The collective findings suggest that through the in vitro engineering of endophytic communities and their in vivo application to Artemisia plants cultivated in tribal population fields, artemisinin production can be significantly augmented. The overall aim of this review to explore the potential of harnessing microbial communities, their functions, and services to enhance the cultivation of medicinal plants. It outlines a promising path toward bolstering artemisinin production, which holds immense promise in the fight against malaria.

Nitrate contamination in water resources, human health risks and its remediation through adsorption: a focused review.

The level of nitrate in water has been increasing considerably all around the world due to vast application of inorganic nitrogen fertiliser and animal manure. Because of nitrate's high solubility in water, human beings are getting exposed to it mainly through various routes including water, food etc. Various regulations have been set for nitrate (45-50 mgNO3-/L) in drinking water to protect health of the infants from the methemoglobinemia, birth defects, thyroid disease, risk of specific cancers, i.e. colorectal, breast and bladder cancer caused due to nitrate poisoning. Different methods like ion exchange, adsorption, biological denitrification etc. have the ability to eliminate the nitrate from the aqueous medium. However, adsorption process got preference over the other approaches because of its simple design and satisfactory results especially with surface modified adsorbents or with mineral-based adsorbents. Different types of adsorbents have been used for this purpose; however, adsorbents derived from the biomass wastes have great adsorption capacities for nitrate such as tea waste-based adsorbents (136.43 mg/g), carbon nanotube (142.86 mg/g), chitosan beads (104 mg/g) and cetyltrimethylammonium bromide modified rice husk (278 mg/g). Therefore, a thorough literature survey has been carried out to formulate this review paper to understand various sources of nitrate pollution, route of exposure to the human beings, ill effects along with discussing the key developments as well as the new advancements reported in procuring low-cost efficient adsorbents for water purification.

Nose to Brain Delivery of Galantamine Loaded Nanoparticles: In-vivo Pharmacodynamic and Biochemical Study in Mice.

BACKGROUND: Presence of blood brain barrier is one of the major hurdle in drug delivery to brain for the treatment of neurological diseases. Alternative and more effective drug delivery approaches have been investigated for the drug targeting to brain in therapeutic range. OBJECTIVE: The present investigation was carried out to improve the galantamine bioavailability in brain by intranasal drug delivery through thiolated chitosan nanoparticles and compared to nasal and oral delivery of its solution using pharmacodynamic activity as well as biochemical estimation. METHODS: Thiolated chitosan (modified) nanoparticles were fabricated using modified ionic gelation method and intranasal delivery is evaluated by reversal of scopolamine induced amnesia and biochemical estimation of acetylcholinesterase activity in Swiss albino mice brain. Scopolamine (0.4 mg/kg, i.p.) was used to induce amnesia. Piracetam (400mg/kg, i.p.) was used as positive control. Mice were treated with galantamine solution (4mg/kg) by oral and nasal route and formulated galantamine nanoparticles (equivalent to 4mg/kg) by intranasal administration for 7 successive days and the results were compared statistically. RESULTS: Intranasal delivery of galantamine loaded thiolated chitosan nanoparticles was found significant (p<0.05) as compared to oral and nasal administration of its solution, by pharmacodynamic study and biochemical estimation of acetylcholinesterase activity in Swiss albino mice brain. CONCLUSION: Significant recovery in amnesia induced mice model by intranasal administration of galantamine loaded thiolated chitosan nanoparticles established the relevance of nose to brain delivery over the conventional oral therapies for the treatment of Alzheimer's disease.

Identification of multi-targeted anti-migraine potential of nystatin and development of its brain targeted chitosan nanoformulation.

The complex pathophysiology involved in migraine necessitates the drug treatment to act on several receptors simultaneously. The present investigation was an attempt to discover the unidentified anti-migraine activity of the already marketed drugs. Shared featured pharmacophore modeling was employed for this purpose on six target receptors (ß2 adrenoceptor, Dopamine D3, 5HT1B, TRPV1, iGluR5 kainate and CGRP), resulting in the generation of five shared featured pharmacophores, which were further subjected to virtual screening of the ligands obtained from Drugbank database. Molecular docking, performed on the obtained hit compounds from virtual screening, indicated nystatin to be the only active lead against the receptors iGluR5 kainate receptor (1VSO), CGRP (3N7R), ß2 adrenoceptor (3NYA) and Dopamine D3 (3PBL) with a high binding energy of -11.1, -10.9, -10.2 and -12kcal/mole respectively. The anti-migraine activity of nystatin was then adjudged by fabricating its brain targeted chitosan nanoparticles. Its brain targeting efficacy, analyzed qualitatively by confocal laser scanning microscopy, demonstrated a significant amount of drug reaching the brain. The pharmacodynamic models on Swiss male albino mice revealed significant anti-migraine activity of the nanoformulation. The present study reports for the first time the therapeutic potential of nystatin in migraine management, hence opening avenues for its future exploration.

Evaluation of safety and efficacy of brain targeted chitosan nanoparticles of minocycline.

The aim of present study was to evaluate the antidepressant-like effects of minocycline hydrochloride (MH); enhance this effect using nanoparticulate drug delivery system; and further evaluate their safety by determining maximum tolerated dose (MTD). Pure drug MH, MH loaded nanoparticles (MHNP) and Tween 80(®) coated MH encapsulated nanoparticles (cMHNP) were explored for antidepressant-like activity in terms of immobility period using despair swim test (DST) and tail suspension test (TST) in mice (dose equivalent to 100mg/kg MH, i.p.). For MTD determination, Wistar rats were treated with gradual increasing doses of MH and cMHNP orally for 28 consecutive days and observed for body weight, weight indices (WI), behavioral, biochemical and histopathological changes until MTD was found. In mice, MH treatment showed antidepressant-like activity and cMHNP treatment significantly improved this effect. On the other hand, no significant effect was observed for MHNP treated group. However, administration of MH in any case did not produce locomotor activation, suggesting that the antidepressant-like effects of MH may not be attributed to the enhanced locomotion. The MTD was found to be 319mg/kg for MH and 350mg/kg for cMHNP (350mg/kg). Thus surface modified nanoparticles (cMHNP) improved the therapeutic efficacy as well as safety of MH.